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Query: EC:3.1.26.4 (RNase H)
 2,751 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The DNA of all species is constantly under threat from both endogenous and exogenous factors, which damage its chemical structure. Probably the most common lesion that arises in cellular DNA is the loss of a base to generate an abasic site, which is usually referred to as an apurinic or apyrimidinic (AP) site. Since these lesions are potentially both cytotoxic and mutagenic, cells of all organisms express dedicated repair enzymes, termed AP endonucleases, to counteract their damaging effects. Indeed, many organisms consider it necessary to express two or more of these lesion-specific endonucleases, underscoring the requirement that exists to remove AP sites for the maintenance of genome integrity and cell viability. Most AP endonucleases are very versatile enzymes, capable of performing numerous additional repair roles. In this article, we review the AP endonuclease class of repair enzymes, with emphasis on the evolutionary conservation of structural features, not only between prokaryotic and eukaryotic homologues, but also between these enzymes and the RNase H domain of one class of reverse transcriptase.
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PMID:Structure and function of apurinic/apyrimidinic endonucleases. 766 52

Endonuclease G (Endo G) is widely distributed among animals and cleaves DNA at double-stranded (dG)n.(dC)n and at single-stranded (dC)n tracts. Endo G is synthesized as a propeptide with an amino-terminal presequence that targets the nuclease to mitochondria. Endo G can also be detected in extranucleolar chromatin. In addition to deoxyribonuclease activities, Endo G also has ribonuclease (RNase) and RNase H activities and specifically cleaves mouse mitochondrial RNA and DNA-RNA substrates containing the origin of heavy-strand DNA replication (OH). The cleavage sites match those found in vivo, indicating that Endo G is capable of generating the RNA primers required by DNA polymerase gamma to initiate replication of mitochondrial DNA.
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PMID:Primers for mitochondrial DNA replication generated by endonuclease G. 768 44

We have examined the stability of long tracts of CAG repeats in yeast mutants defective in enzymes suspected to be involved in lagging strand replication. Alleles of DNA ligase (cdc9-1 and cdc9-2) destabilize CAG tracts in the stable tract orientation, i.e., when CAG serves as the lagging strand template. In this orientation nearly two-thirds of the events recorded in the cdc9-1 mutant were tract expansions. While neither DNA ligase allele significantly increases the frequency of tract-length changes in the unstable orientation, the cdc9-1 mutant produced a significant number of expansions in tracts of this orientation. A mutation in primase (pri2-1) destabilizes tracts in both the stable and the unstable orientations. Mutations in a DNA helicase/deoxyribonuclease (dna2-1) or in two RNase H activities (rnh1Delta and rnh35Delta) do not have a significant effect on CAG repeat tract stability. We interpret our results in terms of the steps of replication that are likely to lead to expansion and to contraction of CAG repeat tracts.
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PMID:The impact of lagging strand replication mutations on the stability of CAG repeat tracts in yeast. 1092 64

Retrotransposons commonly encode a reverse transcriptase (RT), but other functional domains are variable. The acquisition of new domains is the dominant evolutionary force that brings structural variety to retrotransposons. Non-long-terminal-repeat (non-LTR) retrotransposons are classified into two groups by their structure. Early branched non-LTR retrotransposons encode a restriction-like endonuclease (RLE), and recently branched non-LTR retrotransposons encode an apurinic/apyrimidinic endonuclease-like endonuclease (APE). In this study, we report a novel non-LTR retrotransposon family Dualen, identified from the Chlamydomonas reinhardtii genome. Dualen encodes two endonucleases, RLE and APE, with RT, ribonuclease H, and cysteine protease. Phylogenetic analyses of the RT domains revealed that Dualen is positioned at the midpoint between the early-branched and the recently branched groups. In the APE tree, Dualen was branched earlier than the I group and the Jockey group. The ribonuclease H domains among the Dualen family and other non-LTR retrotransposons are monophyletic. Phylogenies of three domains revealed the monophyly of the Dualen family members. The domain structure and the phylogeny of each domain imply that Dualen is a retrotransposon conserving the domain structure just after the acquisition of APE. From these observations, we discuss the evolution of domain structure of non-LTR retrotransposons.
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PMID:An extraordinary retrotransposon family encoding dual endonucleases. 1607 10

Xenopus oocytes have been utilized in a number of laboratories as an experimental system to study a variety of biological processes. Here, we describe its application to functional studies of spliceosomal small nuclear RNAs (snRNAs) in pre-messenger RNA (pre-mRNA) splicing, a process that occurs extremely efficiently in Xenopus oocytes. A DNA oligonucleotide complementary to an snRNA of interest is injected into the oocyte cytoplasm. The oligonucleotide subsequently diffuses into the nucleus and hybridizes to the target snRNA, thereby triggering snRNA degradation via endogenous RNase H activity. By the time the endogenous snRNA is depleted, the DNA oligonucleotide itself is degraded by endogenous deoxyribonuclease (DNase) activity. In principle, this procedure enables one to quantitatively deplete any snRNA of choice. Subsequently, a rescuing snRNA that is constructed in vitro may be injected into the snRNA-depleted oocytes to restore the splicing function. After reconstitution, a radiolabeled splicing substrate is injected into the nuclei of the oocytes. These oocyte nuclei are then manually isolated and used to prepare both nuclear RNA for splicing assays and nuclear extract for spliceosome assembly assays. The ability of an injected rescuing snRNA to reconstitute splicing can therefore be tested. Because all types of rescuing snRNAs (e.g., mutant snRNAs, snRNAs with or without modified nucleotides) can be constructed readily, the results obtained from this procedure provide valuable information on the function of a particular snRNA of interest in pre-mRNA splicing.
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PMID:Pre-mRNA splicing in the nuclei of Xenopus oocytes. 1673 22

The freshwater snail Biomphalaria glabrata is closely associated with the transmission of human schistosomiasis. An ecologically sound method has been proposed to control schistosomiasis using genetically modified snails to displace endemic, susceptible ones. To assess the viability of this form of biological control, studies towards understanding the molecular makeup of the snail relative to the presence of endogenous mobile genetic elements are being undertaken since they can be exploited for genetic transformation studies. We previously cloned a 1.95kb BamHI fragment in B. glabrata (BGR2) with sequence similarity to the human long interspersed nuclear element (LINE or L1). A contiguous, full-length sequence corresponding to BGR2, hereafter-named nimbus (BgI), has been identified from a B. glabrata bacterial artificial chromosome (BAC) library. Sequence analysis of the 65,764bp BAC insert contained one full-length, complete nimbus (BgI) element (element I), two full-length elements (elements II and III) containing deletions and flanked by target site duplications and 10 truncated copies. The intact nimbus (BgI) contained two open-reading frames (ORFs 1 and 2) encoding the characteristic hallmark domains found in non-long terminal repeat retrotransposons belonging to the I-clade; a nucleic acid binding protein in ORF1 and an apurinic/apyrimidinic endonuclease, reverse transcriptase and RNase H in ORF2. Phylogenetic analysis revealed that nimbus (BgI) is closely related to Drosophila (I factor), mosquito Aedes aegypti (MosquI) and chordate ascidian Ciona intestinalis (CiI) retrotransposons. Nimbus (BgI) represents the first complete mobile element characterised from a mollusk that appears to be transcriptionally active and is widely distributed in snails of the neotropics and the Old World.
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PMID:Nimbus (BgI): an active non-LTR retrotransposon of the Schistosoma mansoni snail host Biomphalaria glabrata. 1752 54

The presence of ribonucleoside monophosphates (rNMPs) in nuclear DNA decreases genome stability. To ensure survival despite rNMP insertions, cells have evolved a complex network of DNA repair mechanisms, in which the ribonucleotide excision repair pathway, initiated by type 2 RNase H (RNase HII/2), plays a major role. We recently demonstrated that eukaryotic RNase H2 cannot repair damage, that is, ribose monophosphate abasic (both apurinic or apyrimidinic) site (rAP) or oxidized rNMP embedded in DNA. Currently, it remains unclear why RNase H2 is unable to repair these modified nucleic acids having either only a sugar moiety or an oxidized base. Here, we compared the endoribonuclease specificity of the RNase HII enzymes from the archaeon Pyrococcus abyssi and the bacterium Escherichia coli, examining their ability to process damaged rNMPs embedded in DNA in vitro We found that E. coli RNase HII cleaves both rAP and oxidized rNMP sites. In contrast, like the eukaryotic RNase H2, P. abyssi RNase HII did not display any rAP or oxidized rNMP incision activities, even though it recognized them. Notably, the archaeal enzyme was also inactive on a mismatched rNMP, whereas the E. coli enzyme displayed a strong preference for the mispaired rNMP over the paired rNMP in DNA. On the basis of our biochemical findings and also structural modeling analyses of RNase HII/2 proteins from organisms belonging to all three domains of life, we propose that RNases HII/2's dual roles in ribonucleotide excision repair and RNA/DNA hydrolysis result in limited acceptance of modified rNMPs embedded in DNA.
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PMID:Unlike the Escherichia coli counterpart, archaeal RNase HII cannot process ribose monophosphate abasic sites and oxidized ribonucleotides embedded in DNA. 3130 May 56